Transcriptional analysis of Bacillus subtilis rRNA-tRNA operons. I. The tRNA gene cluster of rrnB has an internal promoter

The bacterial yjdF riboswitch regulates translation through its tRNA-like fold

Unlike most riboswitches, which have one cognate effector, the bacterial yjdF riboswitch binds to diverse azaaromatic compounds, only a subset of which cause it to activate translation. We examined the yjdF aptamer domain by small-angle X-ray scattering, and found that in the presence of activating ligands, the RNA adopts an overall shape similar to that of tRNA. Sequence analyses suggested that the yjdF aptamer is a homolog of tRNA^Lys, and that two of the conserved loops of the riboswitch are equivalent to the D- and T-loops of tRNA, associating to form an elbow-like tertiary interaction. Chemical probing indicated that this association is promoted by activating ligands such as chelerythrine and harmine. In its native mRNA context, activator ligands stabilize the tRNA-like fold of the yjdF aptamer, outcompeting the attenuated state in which its T-loop base-pairs to the Shine-Dalgarno element of the mRNA. Moreover, we demonstrate that the liganded aptamer itself activates translation, as authentic tRNAs, when grafted into mRNA, can potently activate translation. Taken together, our data demonstrate the ability of tRNA to function as a small-molecule responsive cis regulatory element.

Comparative genomics of Mycobacterium mucogenicum and Mycobacterium neoaurum clade members emphasizing tRNA and non-coding RNA

Background

Mycobacteria occupy various ecological niches and can be isolated from soil, tap water and ground water. Several cause diseases in humans and animals. To get deeper insight into our understanding of mycobacterial evolution focusing on tRNA and non-coding (nc)RNA, we conducted a comparative genome analysis of Mycobacterium mucogenicum (Mmuc) and Mycobacterium neoaurum (Mneo) clade members.

Results

Genome sizes for Mmuc- and Mneo-clade members vary between 5.4 and 6.5 Mbps with the complete Mmuc^T (type strain) genome encompassing 6.1 Mbp. The number of tRNA genes range between 46 and 79 (including one pseudo tRNA gene) with 39 tRNA genes common among the members of these clades, while additional tRNA genes were probably acquired through horizontal gene transfer. Selected tRNAs and ncRNAs (RNase P RNA, tmRNA, 4.5S RNA, Ms1 RNA and 6C RNA) are expressed, and the levels for several of these are higher in stationary phase compared to exponentially growing cells. The rare tRNA^IleTAT isoacceptor and two for mycobacteria novel ncRNAs: the Lactobacillales-derived GOLLD RNA and a homolog to the antisense Salmonella typhimurium phage Sar RNA, were shown to be present and expressed in certain Mmuc-clade members.

Conclusions

Phages, IS elements, horizontally transferred tRNA gene clusters, and phage-derived ncRNAs appears to have influenced the evolution of the Mmuc- and Mneo-clades. While the number of predicted coding sequences correlates with genome size, the number of tRNA coding genes does not. The majority of the tRNA genes in mycobacteria are transcribed mainly from single genes and the levels of certain ncRNAs, including RNase P RNA (essential for the processing of tRNAs), are higher at stationary phase compared to exponentially growing cells. We provide supporting evidence that Ms1 RNA represents a mycobacterial 6S RNA variant. The evolutionary routes for the ncRNAs RNase P RNA, tmRNA and Ms1 RNA are different from that of the core genes.

Electronic supplementary material

The online version of this article (10.1186/s12862-019-1447-7) contains supplementary material, which is available to authorized users.

Genetic and transcriptional organization of the Bacillus subtilis spc-alpha region

We used chromosomal walking methods to isolate a 10.8-kb region from the major ribosomal protein (r-protein) gene cluster of Bacillus subtilis (Bs). The gene order in this region, given by gene product, was r-proteins L16-L29-S17-L14-L24-L5-S14-S8-L6-L18-S5-L30-L15-SecY-adenylate kinase (Adk)-methionine aminopeptidase (Map)-initiation factor 1 (IF1)-L36-S13-S11-alpha subunit of RNA polymerase-L17. The region cloned, therefore, contains the homologues for the last three genes of the Escherichia coli (Ec) S10 operon, together with entire spc and alpha operons. This Bs organization differs from the corresponding region in Ec by the inclusion of the genes encoding Adk, Map and IF1 between the genes encoding SecY and L36. Plasmid integration experiments indicated that all 22 genes comprise a single large transcriptional unit controlled from a major promoter which lies upstream from the gene encoding r-protein L16. Promoter probe experiments located lesser activities internal to this large transcriptional unit, the secY and map promoters. The secY promoter region (psecY) contained two activities, each principally functioning in the stationary growth phase when high protein export is required. Thus, the Bs S10-spc-alpha region differs from its Ec counterpart in both genetic and transcriptional organization. Given this difference in transcriptional organization, the mechanisms coordinating expression of the translational apparatus are also likely to differ between Ec and Bs.

Transfer RNA gene organization and RNase P

Mature tRNAs are remarkably similar in all cells. However, the primary transcripts from tRNA genes can vary considerably due to differences in gene organization. RNase P must be able to recognize the elements that are common to all tRNA precursors to accurately remove the 5'-leader sequences.

Staphylococcus aureus has clustered tRNA genes

The polymerase chain reaction (PCR) was used to detect large tRNA gene clusters in Bacillus subtilis, Bacillus badius, Bacillus megaterium, Lactobacillus brevis, Lactobacillus casei, and Staphylococcus aureus. The primers were based on conserved sequences of known gram-positive bacterial tRNA(Arg) and tRNA(Phe) genes. This PCR procedure detected an unusually large tRNA gene cluster in S. aureus. PCR-generated probes were used to identify a 4.5-kb EcoRI fragment that contained 27 tRNA genes immediately 3' to an rRNA operon. Some of these 27 tRNA genes are very similar, but only 1 is exactly repeated in the cluster. The 5' end of this cluster has a gene order similar to that found in the 9- and 21-tRNA gene clusters of B. subtilis. The 3' end of this S. aureus cluster exhibits more similarity to the 16-tRNA gene cluster of B. subtilis. The 24th, 25th, and 26th tRNA genes of this S. aureus tRNA gene cluster code for three similar, unusual Gly-tRNAs that may be used in the synthesis of the peptidoglycan in the cell wall but not in protein synthesis. Southern analysis of restriction digests of S. aureus DNA indicate that there are five to six rRNA operons in this bacterium's genome and that most or all may have large tRNA gene clusters at the 3' end.

Accumulation of bldA-specified tRNA is temporally regulated in Streptomyces coelicolor A3(2)

Deletion of the bldA gene of Streptomyces coelicolor A3(2), which encodes the only tRNA for the rare UUA codon, had no obvious effects on primary growth but interfered with aerial mycelium formation and antibiotic production. To investigate the possible regulatory role of bldA, its transcription start point was identified, and time courses were determined for the appearance of its primary transcript, the processing of the primary transcript to give a mature 5' end, and the apparent efficiency of translation of ampC mRNA, which contains multiple UUA codons. The bldA promoter was active at all times, but processing of the 5' end of the primary transcript was comparatively inefficient in young cultures. This may perhaps involve an antisense RNA, evidence of which was provided by promoter probing and in vitro transcription. The presence of low levels of the processed form of the tRNA in young cultures followed by increased abundance in older cultures contrasted with the pattern observed for accumulation of a different, presumably typical tRNA which was approximately equally abundant throughout growth. The increased accumulation of the 5' processed form of bldA tRNA coincided with more-efficient translation of ampC mRNA in older cultures, supporting the hypothesis that in at least some physiological conditions, bldA may have a regulatory influence on events late in growth, such as morphological differentiation and antibiotic production.

Two tRNA gene clusters associated with rRNA operons rrnD and rrnE in Bacillus subtilis

Sequence analysis of cloned rescued DNA fragments from a Bacillus subtilis strain with an inserted recombinant plasmid in ribosomal operon rrnE revealed the presence of two tRNA genes for Met and Asp at the 3' end of the operon. Probing chromosomal DNA from a strain carrying a plasmid inserted in rrnD with a fragment containing the genetically unassigned cluster of 16 tRNA genes revealed that the cluster is located immediately following the rrnD operon. Our findings show that all 10 rrn operons in B. subtilis are associated with tRNA gene clusters.

A cluster of nine tRNA genes between ribosomal gene operons in Bacillus subtilis

A cluster of nine tRNA genes located in the 1-kb region between ribosomal operons rrnJ and rrnW in Bacillus subtilis has been cloned and sequenced. This cluster contains the genes for tRNA(UACVal), tRNA(UGUThr), tRNA(UUULys), tRNA(UAGLeu). tRNA(GCCGly), tRNA(UAALeu), tRNA(ACGArg), tRNA(UGGPro), and tRNA(UGCAla). The newly discovered tRNA gene cluster combines features of the 3'-end of trnI, a cluster of 6 tRNA genes between ribosomal operons rrnI and rrnH, and of the 5'-end of trnB, a cluster of 21 tRNA genes found immediately 3' to rrnB. Neither the tRNA(UAGLeu) gene nor its product has been found previously in B. subtilis. With the discovery of this new set of tRNA genes, a total of 60 such genes have now been found in B. subtilis. These known genes account for almost all of the tRNA hybridizing restriction fragments of the B. subtilis genome. The 60 known tRNA genes of B. subtilis code for only 28 different anticodons, compared with a total of 41 different anticodons for 78 tRNA genes in Escherichia coli. This may indicate that B. subtilis does not need as many anticodons because of more flexible translation rules, similar to the situation in Mycoplasma capricolum.

Gene encoding the alpha core subunit of Bacillus subtilis RNA polymerase is cotranscribed with the genes for initiation factor 1 and ribosomal proteins B, S13, S11, and L17

We describe the genetic and transcriptional organization of the promoter-distal portion of the Bacillus subtilis alpha operon. By DNA sequence analysis of the region surrounding rpoA, the gene for the alpha core subunit of RNA polymerase, we identified six open reading frames by the similarity of their products to their counterparts in the Escherichia coli transcriptional and translational apparatus. Gene order in this region, given by gene product, was IF1-B-S13-S11-alpha-L17. Gene order in E. coli is similar but not identical: SecY-B-S13-S11-S4-alpha-L17. The B. subtilis alpha region differed most strikingly from E. coli in the presence of IF1 and the absence of ribosomal protein S4, which is the translational regulator of the E. coli alpha operon. In place of the gene for S4, B. subtilis had a 177-base-pair intercistronic region containing two possible promoter sequences. However, experiments with S1 mapping of in vivo transcripts, gene disruptions in the alpha region, and a single-copy transcriptional fusion vector all suggested that these possible promoters were largely inactive during logarithmic growth, that the major promoter for the alpha operon lay upstream from the region cloned, and that the genes in the IF1 to L17 interval were cotranscribed. Thus, the transcriptional organization of the region resembles that of E. coli, wherein the alpha operon is transcribed primarily from the upstream spc promoter, but the absence of the S4 gene suggests that the translational regulation of the region may differ more fundamentally.